Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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OPTICAL SCANNING AND IMAGING SYSTEM AND METHOD
FIELD OF THE INVENTION
The present invention relates to an optical scanning and imaging system. More
spec~cally, the invention relates to a scanning and imaging device that
utilizes
scanning components without mechanical motion, and is particularly suited for
use in
medical imaging.
BACKGROUND OF THE INVENTION
A variety of imaging techniques are used for the medical diagnosis and
treatment of patients. Ultrasound imaging represents a prevalent technique.
Ultrasound uses sound waves to obtain a cross-sectional image of an object.
These waves are radiated by a transducer, directed into the tissues of a
patient,
and reflected from the tissues. The transducer also operates as a receiver to
receive the reflected waves and electronically process them for ultimate
display .
Another imaging technique is referred to as Optical Coherence Tomography
(OCT). OCT uses light, as opposed to sound waves, to obtain a cross-sectional
image of tissue. The use of light allows for faster scanning times than occurs
in
ultrasound technology. The depth of tissue scan in OCT is based on low
coherence interferometry. Low coherence interferometry involves splitting a
light
beam from a low coherence light source into two beams, a sampling beam and a
reference beam. These two beams are then used to form an interferometer. The
sampling beam hits and penetrates the tissue, or other object, under
measurement,
and then reflects from the tissue, carrying information about the reflecting
points
from the surface and the depth of tissue. The reference beam hits a reference
reflector, such as, for example, a mirror or a diffraction grating, and
reflects from
the reference reflector. The reference reflector either moves or is designed
such
that the reflection occurs at different distances from the beam splitting
point and
returns at a different point in time or in space, which actually represents
the depth
of scan. The time for the reference beam to return represents the desirable
depth
of penetration of tissue by the sampling beam.
When the reflected beams meet, intensities from respective points with equal
time delay form interference. A photodetector detects this interference and
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converts it into electrical signals. The signals are electronically processed
and
ultimately displayed, for example, on a computer screen or other monitor.
Obtaining a cross-sectional image of an object involves scanning in both the
axial and lateral direction. Typical visual frame rates used in filming moving
objects
are on the order of 30 Hz. Therefore, to image a moving object, such'as a
beating
heart, for example, a scanner system must be capable of scanning approximately
90,000 data points (assuming 300 data points in both the lateral and axial
directions of the object, which is typical for an imaging area of 1X10 mm2) in
1130
of a second. However, to accomplish lateral scanning, many OCT systems utilize
reciprocally-moving mechanical parts to move the beam of light across the
object
being imaged. These moving parts often cannot move quickly enough to complete
a lateral scan in the requisite time required by the visual frame rate. Thus,
imaging
of moving objects, such as a beating heart, will be incomplete from frame to
frame.
Additionally, the use of such parts creates other obstacles to achieving
effective
scanning. For example, the inertia of moving parts, and their acceleration and
deceleration, causes a non-uniform speed of scan and a reduced speed of data
acquisition. Furthermore, vibrations associated with the moving parts may
result in
additional electronic noise which negatively affects the resolution of scanned
images.
Design and manufacture of an effective scanning device utilizing moving parts
in combination with medical tools such as, for example, a catheter, also
proves
difficult. For instance, it is very difficult to control precisely the motion
of parts on a
tip of a catheter. Furthermore, moving parts generally require more space,
thus
resulting in an increase in the overall size of the device. For catheters and
other
similar medical devices, such an increase in size is undesirable.
Certain scanner systems used in the communications industry exploit the
ability of certain materials to change properties (such as refractive index)
when
subjected to the application of an electromagnetic field. These communications
scanner systems typically include an optically transparent prism positioned
between electrodes. A light beam passing through the prism will be deflected
at
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certain angles depending on the electromagnetic field created by the
electrodes
and applied to the prism. Because
deflection of the light also is a function of wavelength, optimal performance
of these
scanners requires a monochromatic (single wavelength) light source. These
scanning systems therefore typically utilize lasers, which use light having a
narrow
bandwidth, as the source of light.
SUMMARY OF THE INVENTION
The advantages and purpose of the invention will be set forth in part in the
description which follows, and in part will be obvious from the description,
or may
be learned by practice of the invention. The advantages and purpose of the
invention will be realized and attained by means of the elements and
combinations
particularly pointed out in the appended claims.
To attain the advantages and in accordance with the purpose of the invention,
as embodied and broadly described herein, the invention includes an optical
scanning system for imaging an object. The system includes an optical
transmitter
that transmits light to a prism positioned relative to the optical
transmitter, with the
prism receiving the light transmitted by the transmitter. The prism of the
optical
scanning system has an index of refraction that varies with changes in an
applied
electromagnetic field and that remains substantially constant with changes in
wavelength of light within a given wavelength range.
According to another aspect of the present invention, a scanning system for
imaging body tissue includes a catheter having a distal end and a proximal end
and
configured for insertion into a body. An optical transmitter extends through
the
catheter from the proximal end to the distal end and transmits light to a
first lens
positioned relative to the optical transmitter. The first lens transmits a
collimated
beam of light to a prism positioned relative to the first lens and made of a
material
that has an index of refraction that changes with changes in an applied
electromagnetic field. A second lens is disposed in an opening in a distal end
of
the catheter for focusing the light that exits the prism within a
predetermined
angular range.
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According to yet another aspect of the present invention, a method for
imaging an object includes transmitting light in a predetermined wavelength
through an optical transmitter to a prism and applying an electromagnetic
field to
the prism. The method further includes passing the light through the prism
which is
configured to have an index of refraction that changes with the applied
electromagnetic field and that remains substantially constant over a
predetermined
wavelength range of light such that the light that exits the prism deflects at
a
substantially controlled angle.
It is to be understood that both the foregoing general description and the
following detailed description are exemplary and explanatory only and are not
restrictive of the invention, as claimed.
BRIEF DESCRIPTION OF THE DRAWINGS
The accompanying drawings, which are incorporated in and constitute a part
of this specification, illustrate the preferred embodiments of the invention
and,
together with the description, serve to explain the principles of the
invention. In the
drawings,
Figure 1 is a graph of the index of refraction versus wavelength for crown
glass;
Figure 2 is a plan view of a preferred embodiment of an optical scanning
system according to the present invention, with a cutaway perspective of a
catheter
housing several of the scanning system's components; and
Figure 3 is a cutaway perspective view of a portion of the catheter of Figure
2
showing details of the placement of several of the optical scanning system's
components within the catheter.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
This invention generally pertains to a system, and a related method, for
performing imaging of objects, and in particular for medical imaging, that
overcomes the problems associated with imaging scanners that use mechanically
moving parts. For effective performance, particularly in medical imaging, the
system and method must achieve high resolution and scanning rates with a small
device.
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To accomplish these objectives and to overcome the problems associated
with existing devices of this kind, an optical scanning and imaging system for
use,
for example, in medical imaging, according to a preferred embodiment of the
present invention incorporates a prism having an index of refraction that
changes
as a function of an electromagnetic field applied to the prism. By modifying
and
controlling the electromagnetic field applied to the prism, the index of
refraction of
the prism, and thus the angular deflection of the light passing through the
prism,
also can be controlled. The deflected light beam can then be used as the
source
for an OCT system. This accomplishes imaging of the depth of an object over a
lateral dimension of the object without the need for moving components. Thus,
a
complete scanning of an object can occur in a time period consistent with
visual
frame rates of approximately 30 Hz to achieve imaging of moving objects, such
as,
for example, a beating heart, and nonmoving objects. The prism, a means of
generating, controlling, and applying a electromagnetic field to the prism,
and a
means of transmitting light through the prism are incorporated into a medical
device, such as, for example, a catheter. Incorporating the prism into the
medical
imaging device virtually eliminates the problems of vibrations and inertia
caused by
using moving parts with such small devices.
An additional aspect of the present invention according to yet another
preferred embodiment focuses on the selection of the prism material to be used
in
the optical scanning and imaging system. Aside from changing as a function of
electromagnetic field, a material's index of refraction also changes with the
wavelength of incident light. This becomes problematic when using a prism with
an
OCT imaging system because such OCT imaging generally requires non-
monochromatic light sources having a bandwidth of from 25 to 50 nanometers.
Such relatively large bandwidths achieve short coherence, which in turn
results in
high image resolution. However, when using a large bandwidth light source, the
various component wavelengths deflect from the prism at different angles,
resulting
in a relatively wide light beam and degrading image resolution.
Therefore, according to another preferred embodiment of the present
invention, an optical imaging and scanning system incorporates a prism capable
of
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being subject to an electromagnetic field and made of a material which has an
index of refraction that remains substantially constant as the wavelength of
incident
light changes within a defined wavelength range. Furthermore, by carefully
selecting the wavelength range of the light source to be used in the optical
scanning and imaging system, refractive indices of the prism, as well as other
optical components within the system, also can be confined to a relatively
narrow
range. An exemplary relationship between incident wavelength and index of
refraction that is preferred for the prism material of the present invention
is shown
in Figure 1. Figure 1 illustrates how the index of refraction of crown glass
(an
example of a glass used in a variety of optics applications) varies with the
wavelength of incident light. As shown, the index of refraction changes
significantly
over smaller ranges of lower wavelength light. However, at ranges of higher
wavelength light, for example, between approximately 1275 to 1325 nanometers,
the index of refraction remains substantially constant, for example, in a
range of
approximately 1.503823 to 1.503194.
Additional features that result in the effectiveness of such an imaging.device
without mechanically moving parts include a coating on optical components to
modify and control surface indices of refraction, and optical correcting
components,
such as a focusing objective lens, to preserve the tightness of focus for a
given
beam.
Reference will now be made in detail to the present exemplary embodiments
of the invention, examples of which are illustrated in Figures 2 and 3.
Wherever
possible, the same reference numbers will be used throughout the drawings to
refer to the same or like parts.
In accordance with a preferred embodiment of the present invention, an
optical scanning and imaging system 10 using both optical and electrical
energy is
provided. System 10 includes an optical imaging controller 7. Optical imaging
controller 7 further includes a light source, a light detector, and processing
and
imaging electronics (not shown}. A controller 7 of suitable components and
characteristics would be known to one skilled in the art of optical scanning
and
imaging. Optical imaging controller 7 connects to an optical transmitter, such
as an
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optical fiber 5. Optical fiber 5 extends between optical imaging controller 7,
at one
end, to a gradient index (GRIN) lens 3, at a distal end. Optical fiber 5 is
preferably
of the single mode, polarization-maintaining type which is adapted to conduct
optical information. However, it is contemplated that other suitable optical
transmitters or fibers for carrying optical signals may be used with the
'system of the
present invention.
A deflecting prism 1 according to an embodiment of the present invention is
placed adjacent to and spaced from GRIN lens 3 on a side of GRIN lens 3
opposite
to the side to which optical fiber 5 connects. Prism 1 is positioned so that
it may
receive light emitted from lens 3. According to an aspect of the present
invention,
deflecting prism 1 is made of a material that varies its index of refraction
as a
function of an applied electromagnetic field. According to another aspect of
the
present invention, deflecting prism 1 also is made of a material that has a
substantially constant index of refraction with changes in wavelengths within
a
specific wavelength range of incident light. One example of such a material
that
incorporates both of these properties includes silica with additives of rare
earth
metals, such as, for example, lithium-tantalate (LiTa03) or strontium-barium-
niobate
(SBN). Such a material exhibits a similar index of refraction versus
wavelength
characteristic as crown glass shown in Figure 1. That is, the general shape of
the
curve will be similar, although precise numeric values may differ. The various
additives that are used in combination with the silica will affect these
precise values
and should be chosen depending on the desired characteristics, for example,
incident wavelength range, of the scanning system. Other suitable materials
exhibiting similar characteristics also may be used and are within the scope
of the
present invention.
To apply the electromagnetic field to prism 1, an electrode 15 is placed on
each side of prism 1. The electrodes 15 are preferably placed on opposite
prism
sides that are parallel to the plane of deflection of the light that travels
through the
prism. A pair of wires 13 each connect at one end to one of the respective
electrodes 15. At their other ends, wires 13 connect to a scan controller 11.
Scan
controller 11 includes a signal generator and amplifier (not shown).
Electrical
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signals, generated in scan controller 11, travel over wires 13 to electrodes
15 to
create an electromagnetic field of controlled strength that is applied to
prism 1. It is
contemplated that both wires 13 and electrodes 15 are made of copper or
silver, or
other suitable like material capable of conducting electricity and generally
known to
those having ordinary skill in the art. Electrodes 15 preferably are in the
form of
thin plates, however other suitable configurations are contemplated and within
the
scope of the invention. Moreover, any scan controller of suitable components
and
characteristics known to one skilled in the art of optical scanning and
imaging is
within the scope of this invention.
In a preferred embodiment of the present invention, an objective lens 17 is
disposed on a side of prism 1 opposite to the side where GRIN lens 3 is
disposed.
When so disposed, objective lens 17 redirects and focuses a beam of light
passing
through lens 17 to predetermined angular range. Such a lens also aids in
reducing
scatter of the ultimate imaging beam in order to produce a system having an
overall sharper resolution.
As shown in Figures 2 and 3, a preferred use of optical scanning and imaging
system 10 includes disposing the system within a catheter 9. Accordingly, scan
controller 11 and optical imaging system 7 are located outside of catheter 9.
Optical fiber 5 and wires 13 extend from optical imaging system 7 and scan
controller 11, respectively, into a proximal end of catheter 9 and through
catheter 9
to the remaining components of scanning and imaging system 10 located at a
distal end of catheter 9.
Figure 3 illustrates in detail the mounting of optical fiber 5, wires 13, GRIN
lens 3, prism 1, and objective lens 17 within catheter 9. A holder 21 secures
prism
1 with surrounding electrodes 15 to GRIN tens 3. As shown in the Figure,
holder
21 has a substantially U-shaped configuration, with GRIN lens 3 secured to an
apex of the U while the legs of the U clamp around outer surfaces of
electrodes 15
to hold prism 1. Holder 21, thus, is configured to maintain a predetermined
distance between GRIN lens 3 and prism 1. Holder 21 preferably is made from a
material that exhibits high rigidity, strength, and insulating properties,
such as, for
example, polycarbonate or other suitable like material. While Figure 3 shows
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holder 21 having a U-shaped configuration, other configurations are
contemplated
as long as they allow for firm securing of prism 1, electrodes 15, and GRIN
lens 3
relative to each other.
A fixing member 25, preferably in the form of potting compound, secures the
entire assembly, including optical fiber 5, GRIN lens 3, electrical wires 13,
electrodes 15, and holder 21, within catheter 9. Member 25 preferably fills
substantially the entire space between the various components and inner walls
8 of
catheter 9, and extends along a length of catheter 9 from approximately a
distal
end of prism 1 to slightly past a proximal end of GRIN lens 3. It is
contemplated to
use a potting compound such as silicon rubber or epoxy for member 25. However,
other suitable like materials also may be used and would be within the scope
of the
present invention.
Objective lens 17 is secured to the distal opening 18 of catheter 9 using an
adhering member 23. Member 23 is preferably in the form of optical adhesive
having similar optical properties as the incident beam of light used in
conjunction
with optical scanning and imaging system 10, while also being capable of
sealing
the inside of catheter 9 from the penetration of moisture. An example of such
an
optical adhesive includes an adhesive called "Norland Optical Adhesive 61",
supplied by Norland Products, Inc. However, other epoxies or suitable like
optical
adhesives having the desired properties can be used and would be within the
scope of the present invention.
A preferred embodiment of the combined optical scanning system 10 and
catheter 9 has the following dimensions so as to be compatible for use with
typical
endoscopes. Catheter 9 has an outside diameter of approximately 2.7 mm, an
inside diameter of approximately 2.3 mm, and a wall thickness of approximately
0.2
mm. Deflecting prism 1 with attached electrodes 15 is approximately 20 mm
long,
approximately 2.2 mm wide, and approximately 0.5 mm thick. GRIN lens 3
generally has a cylindrical configuration with a diameter of approximately 0.5
mm
and a length of approximately 3 to 5 mm. The overall length of the system from
a
proximal end of GRIN lens 3 to a distal end of objective lens 17 is
approximately 40
mm, including gaps between GRIN lens 3 and prism 1, and prism 1 and objective
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lens 17. These dimensions are meant to be exemplary only. It is contemplated
that the various components' dimensions, as well as the overall system
dimensions, may vary according to the precise procedure the system is used to
perform. For instance, it will be appreciated by persons having ordinary skill
in the
art that the gap between GRIN lens 3 and prism 1 is not critical and can be as
little
as zero since a collimated beam of light exits GRIN lens 3. The gap between
prism
1 and objective lens 17 depends on the focal length of objective lens 17,
which is
designed according to actual deflection angular range exhibited by prism 1 and
the
desired range of angular deflection exiting objective lens 17. The thickness
of
objective lens 17 also may be determined by desired performance
characteristics.
When used for optical scanning and imaging, system 10 works in the
following manner. Light is generated by the light source within optical
imaging
system 7. The wavelength range emitted by the light source is selected as a
function of the material used for prism 1. That is, the incident wavelengths
must be
selected within the range for which the prism material exhibits a relatively
constant
index of refraction over the entire range. Choosing relatively high
wavelengths for
the incident light allows for greater penetration of the depth of the object.
Thus, it is
preferable to select a material for prism 1 that has substantially constant
indices of
refraction over ranges of relatively high wavelengths.
The radiated light from system 7 is polarized in a plane perpendicular to a
plane of scanning and travels along optical fiber 5 and through GRIN lens 3.
From
GRIN lens 3, the light exits as a collimated beam 19 and enters prism 1. Prism
1
deflects collimated beam of light 19 in an angular direction in the scanning
plane.
The deflected light beam 19' then enters objective lens 17 which focuses and
redirects the beam within a predetermined angular range in order to achieve
sharper image resolution.
Light 19" exiting objective lens 17 is then directed to the object to be
imaged.
The reflected light from the object then enters objective lens 17, goes back
through
prism 1, GRIN lens 3, and optical fiber 5 to the optical imaging system 7
where it is
processed and converted into an image, as described earlier with respect to
OCT
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systems generally. The processed image is then displayed on a computer monitor
or other suitable, like display means.
An aspect to the operation of optical scanning and imaging system 10
includes controlling the angle of deflection of light beam 19' exiting
deflecting prism
1. As previously discussed, prism 1 is made of a material that has a varying
index
of refraction with changes in an applied electromagnetic field. Thus, the
refractive
index of prism 1, as welt as the angular deflection of beam 19', can be
controlled
and modified by controlling and modifying the amplitude and frequency of the
electromagnetic field generated between electrodes 15. The signal generator
and
amplifier of scan controller 11 control the frequency and amplitude of the
electromagnetic field, and can be either manually controlled by a user or
automatically controlled using systems generally known to those skilled in the
art.
It will be apparent to those skilled in the art from consideration of the
specification and practice of the invention disclosed herein that various
modifications and variations can be made in the optical scanning and imaging
system according to the present invention. For example, preferred materials
for
component parts of the system, including the prism, have been suggested in the
specification, but other materials having similar properties could be utilized
as well.
Also, the sizes and shapes of the various components, including the GRIN lens,
the prism, the electrodes and the objective lens of the system may differ from
one
embodiment to the next depending on, for example, the medical procedure to be
performed. Various changes in size and shape may also be necessary depending
on the types of objects desired to be imaged and the environments in which the
objects are located. Additionally, it is contemplated to use surface coatings
on
various optical components within the system to alter various properties of
those
components, including, for example, the index of refraction. Selection of
coatings
for the desired properties would be obvious to persons having ordinary skill
in the
art.
Furthermore, although much of the discussion of the optical scanning system
according to the present invention focuses on a system used for medics!
imaging,
and particularly for use in medical imaging catheters for use in a lumen of an
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endoscope or other like device, it is contemplated that the system can be used
for
other imaging processes and for imaging various objects. These other uses
include, for example, other medical applications, including vascular or
nonvascular,
and non-medical applications.
Therefore, the invention in its broader aspects is not limited to the specific
details and illustrative examples shown and described in the specification. It
is
intended that departures may be made from such details without departing from
the
true spirit or scope of the general inventive concept as defined by the
following
claims and their equivalents.
